Multi-button control headset for a mobile communication device

ABSTRACT

The invention is directed at a headset for a mobile communication device having a multi-button control and is implemented with a standard headset jack. The multi-button control is decoded by a microprocessor after which an encoded signal is then transmitted from the processor to the handset. In this manner, by using the standard jack, no additional hardware is required on the handset.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No. 13/173,010, filed Jun. 30, 2011, now U.S. Pat. No. 8,548,538, issued Oct. 1, 2013, which is a continuation of U.S. Pat. No. 7,983,722, issued Jul. 19, 2011, the disclosure of which is incorporated by reference herein in its entirety.

FIELD OF THE INVENTION

The present invention relates generally to headsets for a mobile communication device. More particularly, the present invention relates to a headset for a mobile communication device having a multi-button control and a standard headset jack.

BACKGROUND OF THE INVENTION

When mobile communication devices were first developed, their main functionality was to provide a way for individuals to communicate with other individuals without the need for a landline. As the mobile communication device technology improved, further functionalities such as email, a contact database or a calendar were added. In the latest wave of mobile communication devices, new functionality such as an MP3 player and cameras have been added resulting in a multi-purpose mobile communication device.

In order for users to listen to an MP3 player, a headset is typically required which preferably includes a remote control so that the user is able to control the MP3 player within the mobile communication device. However, these headsets are typically individualized for each mobile communication device. Existing headsets include non-standard headset jacks which are then plugged into a corresponding slot within the unique mobile communication device. Therefore users are required to buy a specific headset which is dependent on the mobile communication device they are using.

Currently, headsets with standard jacks which are used with mobile communication devices have only a single button which is used to mute a call or to initiate voice activated dialing. Typically a single press, or a long press, can activate different functions. However, these single button controls can only provide two different control signals.

Alternatively, some headsets with multiple button controls are implemented with non-standard jacks and thusly, the mobile communication devices are required to be updated in order to be able to receive the non-standard jack. Therefore, additional hardware is required in each mobile communication device in order to receive the non-standard jack. Additional conductors are also required in each of the headsets.

It is, therefore, desirable to provide a novel headset for a mobile communication device having a multi-button control using a standard headset jack.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:

FIG. 1 is a schematic diagram of a mobile communication device and headset;

FIG. 2 is a schematic diagram of circuitry for a headset;

FIG. 3 is a schematic diagram of circuitry for a headset in accordance with an embodiment;

FIG. 4 is a diagram of coding schemes for use with the headset;

FIG. 5 is a schematic diagram of circuitry for a headset in accordance with another embodiment; and

FIG. 6 is a flowchart outlining a method of headset use.

DETAILED DESCRIPTION

Generally, the present embodiment provides a method and system for a headset for a mobile communication device. The headset includes a multi-button control and uses a standard jack for connecting to the mobile communication device.

SUMMARY OF THE INVENTION

The invention is directed at a headset for a mobile communication device having a multi-button control and is implemented with a standard headset jack. The multi-buttons control is decoded by a microprocessor after which an encoded signal is then transmitted, via the microphone line from the processor to the handset. In this manner, by using the standard jack, no additional hardware is required in the handset. Only software to decode the signal on the microphone input is required on the handset.

In one embodiment, there is provided, a headset, including a standard headset jack, having a multi-button control for activating commands on a mobile communication device, the multi-button control comprising a plurality of buttons, each representing at least one of the commands; and a controller, connected to each of the set of buttons; wherein when the controller detects the depression of one of the buttons, the controller determines which button was pressed and transmits a control signal to the mobile communication device corresponding to the button.

In a further embodiment, there is provided a headset for a mobile communication device comprising a set of speakers for transmitting sound from the mobile communication device to a user; a multi-button control for controlling sound from the mobile communication device; and a standard jack for connecting the headset to the mobile communication device and for transmitting signals from the multi-button control to the mobile communication device to provide sound to the speakers.

Turning to FIG. 1, a schematic diagram of a mobile communication device, or handset, 10 having a headset 12 thereby connected is provided. The headset 12 further comprises a multiple button controller 14 having a plurality of buttons 16. The number of buttons is theoretically limitless however, the number is dictated by the size of the controller 14. The headset 12 further includes at least one ear bud 18 each housing a speaker (as shown in FIG. 2). The headset 12 is connected to the mobile communication device 10 via standard jack. A microphone 15 is also included in the headset 12.

Turning to FIG. 2, circuitry 20, typically mounted to a printed circuit board assembly 21, for a standard headset 12 is shown. The headset 12 includes a standard jack, or plug, 22 for connecting the headset to the handset. The plug 22 comprises a microphone portion 24, a left speaker portion 26, a right speaker portion 28 and a ground portion 30. The jack 22 is connected to the circuitry 20 via a plurality of wires 32.

In the current embodiment, the circuitry 20 comprises a set of connectors 34 for receiving the wires 32 from their corresponding locations within the jack 22. The microphone connector 34 a is connected to a first capacitor 36 and an inductor 38. An output of the inductor 38 is connected to plurality of elements connected in parallel. The plurality of elements includes a switch 40, a zener diode 42, a second capacitor 44, a microphone 46 and a third capacitor 48. A second inductor 50 is located between the ground connector 34 b and the output of the parallel elements. The output from the second inductor 50 is connected to ground along with one side of a pair of speakers 52. The left speaker portion connector 34 c and the right speaker portion connector 34 d are also connected to their respective, left and right speakers 52. As will be understood, the speakers are typically located within the ear buds 18 of the headset 12 which are then inserted into a user's ears so that they may listen of the output from the mobile communication device.

In operation, the zener diode 42 is used to control the electrostatic discharge (ESD) which may be experienced within the headset 12. The inductor 38 and the first capacitor 36 provide a wide band filter for the various General Packet radio Services (GPRS) bands. This filter reduces and/or prevents the headset from picking up and transmitting GSM pulses via the microphone line. This is also known as GSM buzz. Finally, the switch 40 shorts out the microphone bias current which is detected by the handset as a signal.

Turning to FIG. 3, a schematic diagram of an embodiment of a headset 12 having a multi-button control 60 in accordance with one embodiment is shown. In each of the embodiments, the headset 12 is implemented with the standard headset jack 22 for connection with the mobile communication device 10. In this embodiment, the circuitry 62 for implementing the multi-button control 60 is shown connected to the standard headset circuitry 20 of FIG. 2 with one substitution. The switch 40 is replaced with a Field-Effect Transistor (FET) 64. The implementation of the multi-button control using a standard headset and standard jack provides the benefit that mobile communication devices do not have to be altered in order to operate with the headset. In this manner, since the mobile communication device does not have to be updated to include extra hardware to receive the headset jack, the mobile communication device may be able to receive the headset disclosed herein or existing headsets with standard jacks and one control button.

Therefore, in order for the handset to recognize which type of headset has been connected, the handset preferably includes circuitry to make this determination. In one embodiment, when the headset detects a microphone bias voltage, a predetermined signal may be transmitted by the headset to be decoded by the handset. This may be implemented by simply connecting an output of a controller 66 to the microphone portion of the plug output of the processor. A filter network 71 may also be located along this connection in order to reduce noise.

The circuitry 62 includes the controller 66, such as a processor, preferably having low power consumption and a battery 68. The battery 68 is preferably a rechargeable battery or a super capacitor which may be charged by a microphone bias when the headset is connected to the mobile communication device. If a microphone bias is used, a voltage boost circuit is likely to be required to boost the voltage on the microphone bias to above 1.8 V. Alternatively, the battery may be a one-time use battery and replaced when the power has been entirely discharged from the battery 68.

A series of switches 70, representing each button on the multi-button control, is connected to the processor 66. In FIG. 3, the switches 70 have been labeled as B1, B2, B3, B4, B5 and B6. For instance, B1 may represent a mute button, B2 may represent a volume up button, B3 may represent a volume down button, B4 may represent a rewind button, B5 may represent a fast forward button and B6 may represent a play/stop button. As will be understood, the number of switches is limitless but is dependent on the physical size of the multi-button control. Each of the switches is also connected to ground 72. Within the processor is a memory, or database 67, for storing control information and a module 69 for determining which switch 70 has been pressed.

In the present embodiment, an output of the processor 66 is connected to the FET 64. As will be described below with respect to the operation of the control 60, this connection provides the necessary signals to control the handset.

FIG. 4 provides examples of various methods of encoding the control signals being transmitted from the headset to the handset. Encoding control signal mode A is directed at multiple presses, encoding control signal mode B is directed at pulse trains, encoding control signal mode C is directed at unique frequencies, encoding control signal mode D is directed a dual tone multiple frequency (DTMF) and encoding control signal mode E is directed at pulse width. It will be understood that each headset preferably operates in only one of the encoding control signal modes but in some embodiments, the headset may operate under multiple control signal modes depending on the required functionality.

In this embodiment, the circuitry is implemented for a multi-button control 60 operating under control signal mode A, control signal mode B or control signal mode E, as shown in FIG. 4. As will be understood, each headset preferably operates in a single control signal mode. However, it will be understood that some embodiments may employ multiple control signal modes. When one of the series of switches 70, or buttons, is pushed, a signal is transmitted to the processor 66 from the switch. The module 69 within the processor 66 receives this signal (step 200 of FIG. 6) and then determines which of the switches 70 has been pressed (step 202). After determining the switch, the module then accesses the database 67 to determine a control signal corresponding to or associated with the pressed switch 70 (step 204).

For instance, if the user wishes to play music, after pressing B6, the software module 69 determines B6 was pressed and accesses the database/memory 67 to determine the signal that needs to be transmitted from the multi-button control to play music.

As shown in FIG. 4, the signal corresponding to B6 for mode A, is a series of 6 pulses. The pulses are then transmitted from the processor 66 to the FET 64. The pulses are recognized by the FET 64 which then translates this pulse signal to the jack 22 (step 206) by shorting out the microphone to ground. The jack 22 then transmits this information to the handset (step 208) which receives the pulse signal. A processor within the handset then processes the pulse signal to determine the command corresponding to the signal transmitted (step 209). In this example, the processor determines that a play music command has been issued and then executes the command and transmits the response to the headset (step 211). Therefore, in this example, the mobile communication device plays music which is then transmitted back through the jack 22 to the headset which then receives the response and transmits the music to the speakers (step 210).

The user is then able to enjoy listening to music on their headset. Similarly, if music is already playing, the user may choose to stop the music, turn the volume up or down by pressing the relevant button. As before, the method outlined in FIG. 6 is performed to transmit the necessary signal to the handset to have the command be performed.

In an alternative embodiment, for instance if the multiple button control was operating in encoding control signal mode B, using a pulse train, the nature of the signals being transmitted from the processor to the headset are shown in FIG. 4. A start pulse is typically transmitted to the FET indicating that a button has been pressed. The start pulse is then followed up with a series of pulses corresponding to the button number that was pressed. For instance if B1 is pressed, a single pulse is provided after the start pulse, if B2 is pressed, two pulses are provided. Similar pulse streams are provided for buttons B3, B4, B5 and B6.

In a more specific example, the start pulse may be a 20 ms pulse with a 10 ms break before the transmission of the stream of control signal pulses, each pulse lasting for 1 ms.

In another embodiment, when square wave pulses are used, the circuitry further includes a set of electronic elements which limit the slew rate of the square wave pulse in order to reduce the potential of the buttons from being heard in the audio transmitted to the speakers. In one embodiment, this may be implemented by adding a resistor/capacitor (RC) network between the FET and the processor 66. Finer slew rate control may be implemented by standard pulse width modulation (PWM) methods.

The pulse train is then transmitted from the FET to the headset 10 via the jack 22. The processor within the headset 10 recognizes the start pulse and processes the following series of pulses to determine which button is pressed. After determining the command from the control, the mobile communication proceeds to execute the demand and the result is transmitted to the user via the speakers.

Turning to FIG. 5, a second embodiment of a multiple button control 14 for a mobile communication device 10 is shown. In this embodiment, the output of the processor is directed connected directly to the jack 22, however the output is transmitted through a voltage divider 74 which is used to ensure that the signal being transmitted to the jack is at a predetermined level comparable to the microphone output. Operation of the embodiment is in an identical manner with respect to the method outlined in FIG. 6. However, the nature of the signals being transmitted by the processor differs. In this embodiment, when operating in Mode C, the control signals are transmitted at different frequencies such that the jack transmits the signal to the headset which deciphers the frequency and then performs the requested task. In an alternative embodiment, the output of the processor may also be connected to the FET 64.

In one implementation, if B1 is pressed, the processor 66 transmits a signal at 3400 Hz which is then received by the handset 10 via the jack 22. Once the handset receives a signal at 3400 Hz, the processor recognizes that B1 has been pressed. Similarly, if B2 is pressed, a signal is transmitted at 3600 Hz to the mobile communication device. In order to prevent any interference, each of the frequencies which are selected and associated with the buttons are outside of the audible range so the user does not experience any interference or distraction.

The battery 68 allows the control to be self-sufficient and does not drain the battery within the mobile communication device. Therefore by utilizing a low power processor, the life of the battery 68 is prolonged and does not have to be changed on a constant basis. The importance of the battery is that no additional connection is required from the handset to provide power to the processor in the headset.

If the headset is operating under Mode D, the signals are selected and differentiated using DTMF.

In an alternative embodiment, the processor 66 may be replaced by an Application Specific Integrated Circuit (ASIC) to lower cost, power consumption and size of the control 16.

In an alternative embodiment, where multiple encoding control signal modes are combined, different functionalities may be provided which are controlled via separate control signal modes. For instance Mode A may be used to control an MP3 player while Mode B may be used as a joystick to play a game on the mobile communication device. In this embodiment, the multiple button control includes a switch or control to determine which mode the headset is operating in order to ensure that the encoding is performed correctly by the processor 66. Another embodiment may include the controller 16 being used as a multi-media control in one mode and as a phone dialer in a second mode.

The embodiment having multiple encoding control signal modes may also allow the headset to have a more universal use in that different handsets may require specific encoding control signal modes.

Alternatively, mobile communication devices may operate currently under one mode but in future implementations, may operate under a second mode. In this manner, the headset may be used for both the currently and future versions of a mobile communication device provide more flexibility to the user.

In the preceding description, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the embodiments of a novel headset. However, it will be apparent to one skilled in the art that these specific details are not required in order to practice the invention. In other instances, well-known electrical structures and circuits are shown in block diagram form in order not to obscure the invention. For example, specific details are not provided as to whether the embodiments of the invention described herein are implemented as a software routine, hardware circuit, firmware, or a combination thereof.

The above-described embodiments of the invention are intended to be examples only. Alterations, modifications and variations can be effected to the particular embodiments by those of skill in the art without departing from the scope of the invention, which is defined solely by the claims appended hereto. 

The invention claimed is:
 1. A headset for use with a mobile communication device, the headset comprising: a standard headset jack plug configured to be received in a port of the mobile communication device; a multi-button control unit configured to activate commands on the mobile communication device, the multi-button control unit including: a set of buttons, each representing one of the commands; and a controller in communication with each button of the set of buttons; the standard headset jack plug including a microphone portion having first and second microphone wires coupled thereto, the first microphone wire associated with a microphone section of a printed circuit board assembly, and the second microphone wire associated with an output of the controller of the multi-button control unit; wherein the controller is configured to detect depression of one of the set of buttons and to transmit an encoded control signal, corresponding to the depressed button, to the standard headset jack plug via the second microphone wire, the encoded control signal comprising a series of voltage pulses, each pulse representing a difference in voltage across the second microphone wire relative to a ground wire.
 2. The headset of claim 1, wherein the controller is one of a processor and an application specific integrated circuit (ASIC).
 3. The headset of claim 1, wherein the encoded control signal is encoded in an encoding control signal mode.
 4. The headset of claim 3, wherein the encoding control signal mode comprises one of: a pulse train control signal mode, a unique frequency control signal mode, a dual tone multiple frequency (DTMF) control signal mode or a pulse width control signal mode.
 5. The headset of claim 4, wherein encoding the control signal mode is one of the pulse train control signal mode or the pulse width control signal mode, and the headset further comprises a filter configured to limit a slew rate of the encoded control signal.
 6. The headset of claim 5, wherein the filter comprises an RC network.
 7. The headset of claim 1, wherein the controller further comprises: a database configured to store control signal information associated with each button of the set of buttons; and a module configured to associate the button depression with an encoded control signal.
 8. The headset of claim 1, wherein the control signal is transmitted by the controller to a Field Effect Transistor (FET) within the headset for transmission to the standard headset jack plug.
 9. The headset of claim 1, wherein the multi-button control unit further comprises a voltage divider.
 10. The headset of claim 1, further comprising a battery configured to power the controller.
 11. The headset of claim 10, wherein the battery comprises one of more of: rechargeable battery, a super capacitor and a one-time use battery.
 12. The headset of claim 1, wherein the controller is powered by a microphone bias voltage supplied by the mobile communication device when the standard headset jack plug is received in the mobile communication device.
 13. The headset of claim 1, further comprising an apparatus for indicating to the mobile communication device a presence of the multi-button control unit when the standard headset jack plug is received in the mobile communication device.
 14. The headset of claim 1, wherein the headset is configured to control an audio function of the mobile communication device in which the commands include one or more of: mute, volume up, volume down, rewind, fast forward and play/stop.
 15. A headset for use with a mobile communication device, the headset comprising: a standard headset jack plug configured to be received in a port of the mobile communication device; a multi-button control unit configured to activate commands on the mobile communication device, the multi-button control unit including: a set of buttons, each representing one of the commands; and a controller in communication with each button of the set of buttons; wherein the controller is configured to detect depression of one of the set of buttons and to transmit an encoded control signal, corresponding to the depressed button, to the standard headset jack plug via a voltage divider and a microphone wire, the encoded control signal comprising a series of voltage pulses, each pulse representing a difference in voltage across the microphone wire relative to a ground wire.
 16. A headset for use with a mobile communication, the headset comprising: a standard headset jack plug configured to be received in a port of the mobile communication device; a multi-button control unit configured to activate commands on the mobile communication device, the multi-button control unit including: a set of buttons, each representing one of the commands; and a controller in communication with each button of the set of buttons; wherein the controller is configured to detect depression of one of the set of buttons and to transmit an encoded control signal, corresponding to the depressed button, to the standard headset jack plug via a filter network and a microphone wire, the encoded control signal comprising a series of voltage pulses, each pulse representing a difference in voltage across the microphone wire relative to a ground wire.
 17. A method of operating a headset for use with a mobile communication device, the method comprising: detecting, with a controller of a multi-button control unit of the headset, a depression of one of a set of buttons of the multi-button control unit, each of the set of buttons configured to activate a command on the mobile communication device; and transmitting an encoded control signal, corresponding to the detected depressed button, to a standard headset jack plug configured to be received in a port of the mobile communication device; the standard headset jack plug including a microphone portion having first and second microphone wires coupled thereto, the first microphone wire associated with a microphone section of a printed circuit board assembly of the headset, and the second microphone wire associated with an output of the controller of the multi-button control unit, such that the encoded control signal is transmitted to the standard headset jack plug via the second microphone wire, wherein the encoded control signal comprises a series of voltage pulses, each pulse representing a difference in voltage across the second microphone wire relative to a ground wire. 